JP2014048993A - Transfer program generation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To appropriately transfer an operation signal and a display signal between a control device and a new HMI device while considerably reducing the work time and errors in designer's design work.SOLUTION: A transfer program generation device includes: a plant control management specification information generation unit 11 which generates plant control management specification information by associating controller addresses and attribute information of display components with each other per display component on the basis of screen information of an old HMI device 3; an HMI variable information generation unit 14 which assigns addresses of an operation signal and addresses of a display signal in a second network to generate them as HMI variable information; a controller variable information generation unit 15 which assigns addresses of the operation signal and the display signal in a first network to generate them as controller variable information; and a transfer program information generation unit 16 which generates a transfer program for transmission/reception of the operation signal and the display signal between the first network and the second network on the basis of the HMI variable information and the controller variable information.

Description

  The present invention relates to a transfer program generation apparatus that generates a transfer program for communicating between a control apparatus connected to an existing network and an HMI (Human Machine Interface) apparatus connected to a new network.

  In general, in a plant control monitoring system centering on a steel plant or the like, a control device controls a plant based on an operation signal received from an operation panel mainly composed of hardware products. A control device accepts an operation signal from an HMI (Human Machine Interface) device, and the control device has undergone a rapid change to one that controls the plant based on the operation signal.

  Furthermore, in such a control and monitoring system to which such an HMI device is applied, in order to flexibly respond to various requirements specifications of plant control and monitoring by the operator side, the HMI device has become multifunctional, and accordingly screen specifications. Has also increased.

  For example, in a control / monitoring system equipped with an HMI device used in a steel plant, the designer who designs the screen of the HMI device has over 10,000 display parts and tens of thousands of operation signals displayed on the screen. It is necessary to register HMI interface signals such as display signals and the like, and a means for improving the efficiency of design work has been desired.

  Therefore, Patent Document 1 discloses a plant monitoring screen for creating a graphical monitoring screen in which graphical data and device names are associated with each other by inputting arbitrary control program data for mechanization / automation of the design work. A creation device has been proposed.

Japanese Patent Laid-Open No. 9-282025

  In addition, with the recent increase in the size of plants, control and monitoring systems have also increased in size. In such large-scale plant control and monitoring systems, the control devices are connected to the control devices via a network. More and more HMI devices are provided.

  In the control / monitoring system having such a configuration, it is necessary to accurately transmit an operation signal and a display signal between the control device and the HMI device.

  However, when the plant monitoring screen creation device described in Patent Document 1 is applied to a large-scale plant control / monitoring system, the designer must manually input information for transmitting and receiving operation signals and display signals. As a result, a great burden is imposed on the designer, a huge amount of work time is required, and work errors are caused.

  Here, an existing HMI device (hereinafter referred to as an old HMI device) connected to an existing network (hereinafter referred to as an old network) is replaced with a new HMI device (hereinafter referred to as a new network). When replacing a new HMI device), it is difficult to connect the new HMI device directly to the existing network, and to connect the control device connected to the existing network directly to the new network. Is also impossible.

  Therefore, it is conceivable to provide a gateway (transfer device) that can be connected to the new and old networks at the same time, and to transfer the operation signal from the new HMI device and the display signal from the control device between the new and old networks via the gateway.

  In order to design a transfer program that is installed in this gateway and transfers between the control device and the new HMI device, it is essential to investigate and decode the control program installed in the control device. In some cases, the control device needs to be modified in accordance with the screen specifications of the new HMI device.

  However, there are many cases in which many years have passed since the installation of the old HMI device, there is a risk that there is no instruction manual, no specifications, and there is no skilled designer who can decode the control program. It was a big burden.

  In other words, it is necessary to decipher the communication program with the old HMI device in the control device, and to design and produce tens of thousands of transfer programs for transferring between the old and new networks. This is a very heavy burden on the designer, requires a lot of work time, and causes work errors.

  The present invention has been made in view of the above-described problems, and appropriately reduces the operation time and work error of the design work by the designer while appropriately controlling the operation signal and the display signal between the control device and the new HMI device. Another object of the present invention is to provide a transfer program generation device that generates a transfer program for performing transfer.

  In order to achieve the above object, a first feature of the transfer program generation device according to the present invention is connected to a first network to which a control device is connected and a second network to which an HMI device is connected, and A transfer program generation device that generates a transfer program applied to a transfer device that transfers an operation signal and a display signal between a control device and the HMI device, the transfer program generation device being connected to the first network, A controller for transmitting and receiving the operation signal and the display signal between the control device and the old HMI device for each display component based on the screen information stored in the old HMI device that has been communicating between Plant control management specification information generating means for generating plant control management specification information by associating an address with attribute information of the display component, and the plant control HMI variable information generating means for allocating the address of the operation signal and the address of the display signal in the second network for each display component based on the physical specification information, and generating as HMI variable information, and the plant control Based on management specification information, an address of the operation signal and the display signal in the first network is assigned to each display component, and controller variable information generation means for generating as controller variable information; and the HMI variable information generation Based on the HMI variable information generated by the means and the controller variable information generated by the controller variable information generating means, the operation signal and the display signal between the first network and the second network A transfer program that generates a transfer program for sending and receiving In further comprising a generation unit, a.

  In order to achieve the above object, a second feature of the transfer program generation device according to the present invention is that the HMI variable information generation means is configured to display the display component based on attribute information of the display component of the plant control management specification information. Each time, the address of the operation signal and the address of the display signal in the second network are assigned and generated as HMI variable information, and the controller variable information generating means is based on the controller address of the plant control management specification information Then, for each display component, an address of the operation signal and the display signal in the first network is assigned and generated as controller variable information.

  In order to achieve the above object, a third feature of the transfer program generation device according to the present invention is that the plant control management specification information generation means is connected to the first network and communicates with the control device. Based on the screen information stored in the old HMI device, the component type name uniquely identifying the type of the display component for each display component, and the operation signal between the control device and the old HMI device And generating the plant control management specification information by associating the controller address for transmitting and receiving the display signal with the attribute information of the display component, and for each component type name, the number of bits of the operation signal and the display signal The allocation processing rule storage means for associating and storing the number of bits as an allocation processing rule is further provided, wherein the HMI variable information generation means is the plant system. Based on the management specification information and the allocation processing rule, the operation signal address and the display signal address in the second network are assigned to each display component, and generated as HMI variable information. The information generating means assigns addresses of the operation signal and the display signal in the first network for each display component based on the plant control management specification information and the allocation processing rule, and serves as controller variable information. It is to generate.

  In order to achieve the above object, a fourth feature of the transfer program generation device according to the present invention is that the HMI variable information generation means includes the display component attribute information of the plant control management specification information and the allocation processing rule. Based on this, for each display component, the operation signal address and the display signal address in the second network are assigned and generated as HMI variable information, and the controller variable information generation means includes the plant control management specification. Based on the controller address of the information and the allocation processing rule, an address of the operation signal and the display signal in the first network is assigned to each display component to generate controller variable information.

  According to the transfer program generation device of the present invention, it is possible to appropriately transfer operation signals and display signals between the control device and the new HMI device while greatly reducing the work time and work errors of the design work by the designer. Transfer program can be generated.

It is a block diagram which shows the structure of the control monitoring system to which the transfer program production | generation apparatus which concerns on the 1st Embodiment of this invention was applied. It is the figure which showed an example of the monitoring screen displayed on the new HMI apparatus. It is a block diagram which shows the structure of the control monitoring system to which the transfer program production | generation apparatus which concerns on the 1st Embodiment of this invention was applied. It is the figure which showed an example of the allocation process rule memorize | stored in the allocation process rule memory | storage part of the transfer program generation apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows the operation | movement outline | summary of the transfer program production | generation apparatus which concerns on the 1st Embodiment of this invention. It is the figure which showed an example of the plant control management specification information memorize | stored in the plant control management specification information storage part of the transfer program generation apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the HMI variable information generation process in the transfer program generation apparatus which concerns on the 1st Embodiment of this invention. It is the figure which showed an example of the HMI variable information produced | generated by the HMI variable information production | generation part of the transfer program production | generation apparatus which concerns on the 1st Embodiment of this invention. It is a flowchart which shows the process sequence of the controller variable information generation process in the transfer program generation apparatus which concerns on the 1st Embodiment of this invention. It is the figure which showed an example of the controller variable information produced | generated by the controller variable information production | generation part of the transfer program production | generation apparatus which concerns on the 1st Embodiment of this invention. It is the flowchart explaining the process sequence of the transfer program generation process in the transfer program generation apparatus which concerns on the 1st Embodiment of this invention. It is the figure which showed an example of the transfer program produced | generated by the transfer program production | generation apparatus which concerns on the 1st Embodiment of this invention.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

<First Embodiment>
FIG. 1 is a configuration diagram showing a configuration of a control monitoring system 10 to which a transfer program generation device according to a first embodiment of the present invention is applied.

  As shown in FIG. 1, the control monitoring system 10 to which the transfer program generating device 1 according to the first embodiment is applied includes a transfer program generating device 1, a control device 2 connected to a first network 8, 2 includes an HMI (Human Machine Interface) device 4 (hereinafter referred to as a new HMI device 4) connected to the network 9, and a transfer device 5 connected to the first network 8 and the second network 9. For the sake of explanation, FIG. 1 illustrates an HMI device 3 (hereinafter referred to as an old HMI device 3) connected to the first network 8. When this old HMI device 3 was connected to the first network 8, it was in communication with the control device 2 via the first network 8, and was replaced with the new HMI device 4 due to aging. It is.

  When the old HMI device 3 is connected to the control device 2 via the first network 8 before the replacement, the old HMI device 3 displays a monitoring screen based on the screen information stored therein, and also displays the monitoring screen by the user. An operation signal is generated based on the operation, and the generated operation signal is transmitted to the control device 2 via the first network 8. Further, the old HMI device 3 displays a display component on the monitoring screen based on the display signal received from the control device 2 via the first network 8. The monitoring screen includes a screen used for the user to monitor the plant that is the control target and a screen used for the user to operate the plant that is the control target.

  Here, when the old HMI device 3 connected to the first network 8 which is an existing network is replaced with the new new HMI device 4 connected to the second network 9 which is a new network, the first network 8 and Since the communication standard and the like are different from those of the second network 9, it is difficult to directly connect the new HMI device to the first network 8, and the control device 2 connected to the first network 8 is It is difficult to connect to the second network 9 directly.

  Therefore, the control monitoring system 10 is provided with a transfer device 5 that can be connected to the first network 8 and the second network 9, and the operation signal from the new HMI device 4 and the display signal from the control device 2 are transferred to the transfer device 5. Let the transfer through.

  The new HMI device 4 is connected to the control device 2 via the second network 9 by being replaced with the old HMI device 3. The new HMI device 4 displays a monitoring screen based on the screen information stored therein, generates an operation signal based on the operation of the monitoring screen by the user, and sends the generated operation signal to the control device 2. It transmits via the second network 9. Further, the new HMI device 4 displays a display component on the monitoring screen based on the display signal received from the control device 2 via the second network 9. The monitoring screen includes a screen used for the user to monitor the plant that is the control target and a screen used for the user to operate the plant that is the control target.

  The control device 2 controls various plant devices (not shown) based on the operation signal received from the old HMI device 3 via the first network 8 before the replacement from the old HMI device 3 to the new HMI device 4. . In addition, the control device 2 generates a display signal for displaying a display component on the monitoring screen of the old HMI device 3, and transmits the generated display signal to the old HMI device 3 via the first network 8. .

  In addition, after the replacement from the old HMI device 3 to the new HMI device 4, the control device 2 allows various plant devices (not shown) based on the operation signal received from the new HMI device 4 via the second network 9. Control. Further, the control device 2 generates a display signal for displaying a display component on the monitoring screen of the new HMI device 4 and transmits the generated display signal to the new HMI device 4 via the second network 9. .

  FIG. 2 is a diagram illustrating an example of a monitoring screen displayed on the new HMI device 4. The old HMI device 3 also has the same monitoring screen.

  As shown in FIG. 2, the displayed monitoring screen displays a display frame indicating an area for displaying a display component corresponding to an operation end of a plant device such as a heater or a pump, and each operation end includes An operation end name 131 and an operation display item 132 are displayed.

  In addition, various display components 151 are arranged on the monitoring screen. When the user presses the display component 151 on the monitoring screen, an operation signal corresponding to the pressed display component 151 is generated. To do.

  Thus, since the transfer device 5 connected to the first network 8 and the second network 9 transfers the operation signal from the new HMI device 4 and the display signal from the control device 2, the operation signal and the display signal are transferred. On the other hand, it is necessary to give an address to each of the first network 8 and the second network 9. Then, by associating the assigned addresses, the operation signal and the display signal are appropriately transferred between the first network 8 and the second network 9. Here, the address refers to an address of a memory provided in the transfer device 5, and includes a memory address used for communication on the first network 8 side and a memory address used for communication on the second network 9 side. included.

  The transfer program generation device 1 is installed in the transfer device 5 and generates a transfer program for transferring operation signals and display signals between the control device 2 and the new HMI device 4.

  FIG. 3 is a configuration diagram showing the configuration of the control monitoring system 10 to which the transfer program generation device according to the first embodiment of the present invention is applied.

  The transfer program generation device 1 includes a plant control management specification information generation unit 11, a plant control management specification information storage unit 12, an allocation processing rule storage unit 13, an HMI variable information generation unit 14, and a controller variable information generation unit 15. A transfer program information generation unit 16.

  The plant control management specification information generation unit 11 is connected to the first network 8 and is displayed for each display component based on the screen information stored in the old HMI device 3 communicating with the control device 2. Plant control management specification information is generated by associating a component type name that uniquely identifies the type of the component, a controller address, and attribute information of the display component. Here, the controller address is an address for transmitting and receiving an operation signal and a display signal between the control device 2 and the old HMI device 3, and for example, an address of a memory of the control device 2 is used.

  The plant control management specification information storage unit 12 is configured by, for example, a hard disk drive and stores the plant control management specification information generated by the plant control management specification information generation unit 11.

  The allocation processing rule storage unit 13 is composed of, for example, a ROM or the like, and stores the number of bits of the operation signal and the number of bits of the display signal in association with each part type name and stores them as an allocation processing rule.

  FIG. 4 is a diagram showing an example of the allocation process rules stored in the allocation process rule storage unit 13.

  As shown in FIG. 4, the allocation processing rule 801 stores a part type name 802, an operation signal bit number 803, and a display signal bit number 804 in association with each other.

  The HMI variable information generation unit 14 assigns the address of the operation signal and the address of the display signal in the second network 9 for each display component based on the plant control management specification information and the allocation processing rule, and generates the HMI variable information. To do.

  The controller variable information generation unit 15 assigns the addresses of the operation signal and the display signal in the first network 8 for each display component based on the plant control management specification information and the allocation processing rule, and generates the controller variable information.

  The transfer program information generation unit 16 is based on the HMI variable information generated by the HMI variable information generation unit 14 and the controller variable information generated by the controller variable information generation unit 15, and the first network 8 and the second network 9. A transfer program for transmitting / receiving operation signals and display signals to / from is generated.

  The transfer program storage unit 17 is composed of, for example, a hard disk drive or the like, and stores the transfer program generated by the transfer program information generation unit 16.

<< Operation of Transfer Program Generation Device 1 >>
FIG. 5 is a flowchart showing an outline of the operation of the transfer program generation device 1 according to the first embodiment of the present invention.

  As shown in FIG. 5, the transfer program generation device 1 according to the first embodiment of the present invention reads a design support program from a hard disk (not shown) and executes the read design support program. The control management specification information generation unit 11 extracts screen information from the old HMI device 3 (step S101).

  Next, the plant control management specification information generation unit 11 based on the screen information from the old HMI device 3, for each monitoring screen, at least the part name of the display part and the part type name that uniquely identifies the type of the display part Then, the plant control management specification information is generated in association with the attribute information of the display component (step S103).

  FIG. 6 is a diagram illustrating an example of plant control management specification information stored in the plant control management specification information storage unit 12.

  As shown in FIG. 6, the plant control management specification information 501 is stored in association with a part name 502, a part type name 503, position information 504, display part attribute information 505, and a controller address 506. Yes. Further, the position information 504 includes the x-coordinate and the y-coordinate that are the coordinates of the screen information, and the attribute information 505 includes, for example, the color of the operation button included in the display component and the display for displaying on the button. The name is included. The controller address 506 is an address for transmitting and receiving display signals and operation signals between the control device and the old HMI device 3 in the first network 8.

  Next, the HMI variable information generation unit 14 executes an HMI variable information generation process (step S105). Thereby, the HMI variable information generating unit 14 generates HMI variable information.

  And the controller variable information generation part 15 performs a controller variable information generation process (step S107). Thereby, the controller variable information generation part 15 produces | generates controller variable information.

  Next, the transfer program information generation unit 16 executes a transfer program generation process (step S109). As a result, the transfer program information generation unit 16 generates a transfer program.

((HMI variable information generation process))
FIG. 7 is a flowchart showing a processing procedure of HMI variable information generation processing in the transfer program generation device 1 according to the first embodiment of the present invention.

  First, the HMI variable information generation unit 14 of the transfer program generation device 1 reads the plant control management specification information stored in the plant control management specification information storage unit 12 and sets the number of part names in the plant control management specification information as a variable N. Substitution is performed, and “1” is substituted as an initial value for the counter variable i (step S201).

  Next, the HMI variable information generation unit 14 reads the allocation processing rule stored in the allocation processing rule storage unit 13 (step S203).

  And when it determines with the value of the counter variable i being less than N (step S205: YES), the HMI variable information generation part 14 is i-th among the plant control management specification information read in step S201. From the plant control management specification information corresponding to the part name, an address in the second network is assigned based on the allocation rule read in step S203 (step S207). Specifically, the HMI variable information generation unit 14 exceeds the number of bits of the operation signal and the number of display signals included in the allocation processing rule read from the plant control management specification information corresponding to the i-th part name. In order to prevent the operation signal from being transmitted from the new HMI device 4 to the control device 2 and from the control device 2 to the new HMI device 4 based on the component name, component type name, position information, and attribute information. A variable name and an address in the second network 9 are assigned to the display signal.

  Then, the HMI variable information generation unit 14 associates the variable name with the assigned address in the second network for each display component, and generates the HMI variable information (step S209).

  FIG. 8 is a diagram illustrating an example of HMI variable information generated by the HMI variable information generation unit 14.

  As shown in FIG. 8, a component name 602, an operation signal address 603 in the second network, a display signal address 604 in the second network, an operation signal variable name 605, and a display signal variable name 606. It is associated and stored as HMI variable information.

  Returning to FIG. 7, the HMI variable information generation unit 14 increments the value of the counter i by “1” (step S211).

  And the HMI variable information generation part 14 produces | generates HMI variable information about all the component names contained in plant control management specification information by repeatedly performing the process of step S205-S211.

  If it is determined in step S205 that the value of the counter variable i is equal to or greater than N, the HMI variable information generation unit 14 ends the process (step S205: NO).

  As described above, the HMI variable information generation unit 14 assigns the address of the operation signal and the address of the display signal in the second network 9 for each display component based on the plant control management specification information and the allocation processing rule, and the HMI Generate as variable information.

((Controller variable information generation process))
FIG. 9 is a flowchart showing a processing procedure of controller variable information generation processing in the transfer program generation device 1 according to the first embodiment of the present invention.

  First, the controller variable information generation unit 15 of the transfer program generation device 1 reads the plant control management specification information stored in the plant control management specification information storage unit 12, and sets the number of part names in the plant control management specification information to the variable N. Substitution is performed, and “1” is substituted as an initial value for the counter variable i (step S301).

  Next, the controller variable information generation unit 15 reads the allocation processing rule stored in the allocation processing rule storage unit 13 (step S303).

  And when it determines with the value of the counter variable i being less than N (step S305: YES), the controller variable information generation part 15 is the i-th plant control management specification information read in step S301. A memory address is assigned from the plant control management specification information corresponding to the part name based on the assignment rule read in step S303 (step S307). Specifically, the controller variable information generation unit 15 exceeds the number of bits of the operation signal and the number of display signals included in the allocation processing rule read from the plant control management specification information corresponding to the i-th part name. In order to prevent the operation signal transmitted from the new HMI device 4 to the control device 2 and the display signal transmitted from the control device 2 to the new HMI device 4 based on the component name, the component type name, and the controller address. Thus, a variable name and an address in the first network 8 are assigned.

  Then, the controller variable information generation unit 15 associates the variable name with the assigned address in the first network 8 for each display component, and generates controller variable information (step S309).

  FIG. 10 is a diagram illustrating an example of the controller variable information generated by the controller variable information generation unit 15.

  As shown in FIG. 10, the part name 702, the address 703 of the operation signal in the first network 8, the address 704 of the display signal in the first network 8, the variable name 705 of the operation signal, and the variable name 706 of the display signal. Are stored as controller variable information.

  Returning to FIG. 9, the controller variable information generation unit 15 increments the value of the counter i by “1” (step S311).

  And the controller variable information production | generation part 15 produces | generates controller variable information about all the component names contained in plant control management specification information by repeatedly performing the process of step S307-S311.

  If it is determined in step S305 that the value of the counter variable i is equal to or greater than N, the controller variable information generation unit 15 ends the process (step S305: NO).

  In this way, the controller variable information generation unit 15 assigns the address of the operation signal and the address of the display signal in the first network 8 for each display component based on the plant control management specification information and the allocation processing rule. Generated as controller variable information.

((Transfer program information generation process))
FIG. 11 is a flowchart illustrating a processing procedure of transfer program generation processing in the transfer program generation device 1 according to the first embodiment of the present invention.

  First, the transfer program information generation unit 16 of the transfer program generation device 1 determines whether or not HMI variable information has been generated (step S401).

  Next, the transfer program information generation unit 16 determines whether or not controller variable information has been generated (step S403).

  When it is determined in step S403 that the controller variable information has been generated (in the case of YES), the transfer program information generation unit 16 substitutes the number of component names of the HMI variable information or the controller variable information into the variable N, and the counter variable “1” is substituted for i as an initial value (step S405).

  Next, when it is determined that the value of the counter variable i is less than N (step S407: YES), the transfer program information generation unit 16 converts the i-th HMI variable information into controller variable information. Is generated (step S409).

  Then, the transfer program information generation unit 16 generates an HMI conversion program that converts the i-th controller variable information into HMI variable information (step S411).

  Next, the transfer program information generation unit 16 increments the value of the counter i by “1” (step S413).

  Then, the transfer program information generation unit 16 generates an HMI conversion program and a controller conversion program for all component names included in the HMI variable information and the controller variable information by repeatedly executing the processes of steps S407 to S413.

  When it is determined in step S407 that the value of the counter variable i is N or more, the transfer program information generation unit 16 combines the generated HMI conversion program and the controller conversion program to generate a transfer program, and the transfer program It memorize | stores in the memory | storage part 17 (step S415).

  In this way, the transfer program information generation unit 16 uses the first network 8 based on the HMI variable information generated by the HMI variable information generation unit 14 and the controller variable information generated by the controller variable information generation unit 15. And a transfer program for transmitting and receiving operation signals and display signals between the network 9 and the second network 9.

  FIG. 12 is a diagram showing an example of a transfer program generated by the transfer program generation device 1 according to the first embodiment of the present invention.

  As shown in FIG. 12, the transfer program associates the input variable 901 with the output variable 902 so that the output variable 902 becomes one-to-one.

  In the controller conversion program included in the transfer program, the HMI variable information becomes the input variable 901 and the controller variable information becomes the output variable 902.

  By this controller conversion program, the address of the operation signal in the second network 9 is associated with the address of the operation signal in the first network 8, and the address of the display signal in the second network 9 is the same as the display signal in the first network 8. It is associated with the address.

  In the HMI conversion program included in the transfer program, the controller variable information becomes the input variable 901 and the HMI variable information becomes the output variable 902.

  With this HMI conversion program, the address of the operation signal in the first network 8 is associated with the address of the operation signal in the second network 9, and the address of the display signal in the first network 8 is the address of the display signal in the second network 9. It is associated with the address.

  As described above, according to the transfer program generation device 1 according to the first embodiment of the present invention, it is stored in the old HMI device 3 connected to the first network 8 and communicating with the control device 2. A plant that generates plant control management specification information by associating the controller address for communication between the control device 2 and the old HMI device 3 with the display component attribute information for each display component based on the screen information. HMI variable information that is generated as HMI variable information by assigning the address of the operation signal and the address of the display signal in the second network 9 to each display component based on the control management specification information generation unit 11 and the plant control management specification information. Based on the generation unit 14 and the plant control management specification information, the address of the operation signal and the display signal in the first network 8 is assigned for each display component. Based on the controller variable information generation unit 15 generated as the controller variable information, the HMI variable information generated by the HMI variable information generation unit 14, and the controller variable information generated by the controller variable information generation unit 15, Since the transfer program information generation unit 16 that generates a transfer program for transmitting and receiving operation signals and display signals between the first network 8 and the second network 9 is provided, the work time and work mistakes of the design work by the designer are reduced. It is possible to generate a transfer program for performing data transfer between the control device 2 and the new HMI device 4 while greatly reducing it.

DESCRIPTION OF SYMBOLS 1 ... Transfer program production | generation apparatus 2 ... Control apparatus 3 ... Old HMI apparatus 4 ... New HMI apparatus 5 ... Transfer apparatus 8 ... 1st network 9 ... 2nd network 10 ... Control monitoring system 11 ... Plant control management specification information generation part (plant) Control management specification information generation means)
DESCRIPTION OF SYMBOLS 12 ... Plant control management specification information storage part 13 ... Allocation process rule storage part 14 ... HMI variable information generation part (HMI variable information generation means)
15 ... Controller variable information generation unit (controller variable information generation means)
16: Transfer program information generation unit (transfer program generation means)
17 ... Transfer program storage unit

Claims (4)

Applied to a transfer device connected to a first network to which a control device is connected and a second network to which an HMI device is connected, and transferring an operation signal and a display signal between the control device and the HMI device. A transfer program generation device for generating a transfer program to be executed,
Based on the screen information stored in the old HMI device connected to the first network and communicating with the control device, between the control device and the old HMI device for each display component. A plant control management specification information generating means for generating plant control management specification information by associating the controller address for transmitting and receiving the operation signal and the display signal and the attribute information of the display component;
HMI variable information generating means for allocating the address of the operation signal and the address of the display signal in the second network for each display component based on the plant control management specification information, and generating as HMI variable information;
Based on the plant control management specification information, for each display component, controller variable information generating means for assigning addresses of the operation signal and the display signal in the first network and generating as controller variable information;
Based on the HMI variable information generated by the HMI variable information generation means and the controller variable information generated by the controller variable information generation means, the operation is performed between the first network and the second network. Transfer program generating means for generating a transfer program for transmitting and receiving a signal and the display signal;
A transfer program generation apparatus comprising: The HMI variable information generation means includes:
Based on the attribute information of the display component of the plant control management specification information, an address of the operation signal and an address of the display signal in the second network are assigned to each display component, and generated as HMI variable information. ,
Controller variable information generation means
Based on the controller address of the plant control management specification information, an address of the operation signal and the display signal in the first network is assigned to each display component and generated as controller variable information. The transfer program generation device according to claim 1. The plant control management specification information generating means is
A component type that uniquely identifies the type of the display component for each display component based on the screen information stored in the old HMI device that is connected to the first network and communicated with the control device Generating plant control management specification information by associating a name, a controller address for transmitting and receiving the operation signal and the display signal between the control device and the old HMI device, and attribute information of the display component;
For each part type name, further comprising the allocation processing rule storage means for storing the number of bits of the operation signal and the number of bits of the display signal in association with each other as an allocation processing rule,
The HMI variable information generation means includes:
Based on the plant control management specification information and the assignment processing rule, assign the address of the operation signal and the address of the display signal in the second network for each display component, and generate HMI variable information,
The controller variable information generating means includes
Based on the plant control management specification information and the assignment processing rule, addresses of the operation signal and the display signal in the first network are assigned to each display component and generated as controller variable information. The transfer program generation device according to claim 1. The HMI variable information generation means includes:
Based on the display component attribute information of the plant control management specification information and the allocation processing rule, for each display component, assign the address of the operation signal and the address of the display signal in the second network, Generated as HMI variable information,
The controller variable information generating means includes
Based on the controller address of the plant control management specification information and the allocation processing rule, the address of the operation signal and the display signal in the first network is assigned to each display component, and generated as controller variable information The transfer program generation device according to claim 3, wherein:

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